Laser system with doped fiber components

ABSTRACT

A laser amplifier includes a pump source and an optically active fiber having an input portion configured to receive a signal source and an output portion. The pump source is optically coupled to the optically active fiber. The laser amplifier also includes an output fiber optically coupled to the output portion of the optically active fiber. The output fiber includes a rare-earth element. The laser amplifier further includes a beam expansion section joined to the output fiber.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of prior application Ser. No.12/263,378, filed Oct. 31, 2008.

BACKGROUND OF THE INVENTION

The present invention relates generally to the field of optical systems.More particularly, the present invention relates to a method andapparatus for providing high power laser outputs useful for industrialapplications such as trimming, marking, cutting, and welding. Merely byway of example, the invention has been applied to a relay fiberincluding a rare earth dopant optically coupled to an output of a fiberamplifier. However, the present invention has broader applicability andcan be applied to other optical components including opticalcirculators, optical isolators, end caps, pump combiners, opticalmodulators, optical switching elements, wavelength-division multiplexing(WDM) elements, fiber gratings, beam shaping elements, optical taps,Diffractive Optical Elements (DOE), and the like.

Conventional laser-based material processing has generally used highpeak power pulsed lasers, for example, Q-switched Nd:YAG lasersoperating at 1064 nm, for marking, engraving, micro-machining, andcutting applications. More recently, laser systems based on fiber gainmedia have been developed. In some of these fiber-based laser systems,fiber amplifiers are utilized.

Some optical amplifiers and lasers utilizing a fiber gain medium areoptically pumped, often by using semiconductor pump lasers. The fibergain medium is typically made of silica glass doped with rare-earthelements. The choice of the rare-earth elements and the composition ofthe fiber gain medium depend on the particular application. One suchrare-earth element is ytterbium, which is used for optical amplifiersand lasers emitting in the 1020 nm-1100 nm range. Another rare-earthelement used in some fiber gain media is erbium, which is used foroptical amplifiers and lasers emitting in the 1530 nm-1560 nm range.

The wavelength of the optical pump source used for ytterbium-doped fiberamplifiers and lasers is typically in the wavelength range of 910 nm to980 nm. The wavelength of the optical pump source used for erbium-dopedfiber amplifiers and lasers is typically in a wavelength range centeredat about 980 nm or about 1480 nm.

When a fiber laser or amplifier is operated in a high power mode,variations in the electric field of the light beam in the optical fiberproduce acoustic vibrations in the fiber via electrostriction. Thisacousto-optic interaction between light and acoustic phonons in thefiber, referred to as Stimulated Brillouin Scattering (SBS), results inan interference pattern that feeds a coherent traveling acoustic wave.This wave eventually becomes highly reflective and substantiallydegrades system performance. SBS tends to limit the power outputavailable from fiber amplifier and laser systems. Thus, there is a needin the art for improved methods and systems to increase the output powerof optically active fiber systems.

SUMMARY OF THE INVENTION

Embodiments of the present inventions relate to systems and methods thatreduce SBS present in fibers coupled or connected to one or more opticalcomponents.

According to an embodiment of the present invention, a laser amplifieris provided. The laser amplifier includes a pump source and an opticallyactive fiber having an input portion configured to receive a signalsource and an output portion. The pump source is optically coupled tothe optically active fiber. The laser amplifier also includes an outputfiber optically coupled to the output portion of the optically activefiber. The output fiber includes a rare-earth element. The laseramplifier further includes a beam expansion section joined to the outputfiber.

According to another embodiment of the present invention, an opticalisolator system is provided. The optical isolator system includes anoptically active input fiber and an optical element having an input andan output. The input is coupled to the optically active input fiber. Theoptical element is characterized by an optic axis, a first transmittancein a first direction along the optic axis, and a second transmittanceless than the first transmittance in a second direction opposite to thefirst direction. The optical isolator system also includes an outputfiber coupled to the output of the optical element.

According to an alternative embodiment of the present invention, a lasersource is provided. The laser source includes a seed source and anoptical circulator including a first port coupled to the seed source, asecond port, and a third port. The laser source also includes anamplitude modulator characterized by a first side and a second side. Thefirst side is coupled to the second port of the optical circulator. Thelaser source further includes a first fiber amplifier characterized byan input end and a reflective end. The input end is coupled to thesecond side of the amplitude modulator. The first fiber amplifierincludes an active fiber section and a pump source coupled to the activefiber section by a pump coupler. The pump coupler includes a rare-earthdoped fiber. Moreover, the laser source includes a second fiberamplifier coupled to the third port of the optical circulator.

According to another alternative embodiment of the present invention, anoptical coupler is provided. The optical coupler includes a first fiberincluding an input facet configured to receive a pump source and asecond fiber including an input facet configured to receive a signalsource. The second fiber includes a rare-earth dopant ion. The opticalcoupler further includes a coupling section between the first fiber andthe second fiber.

According to a specific embodiment of the present invention, an opticalbeam splitter is provided. The optical beam splitter includes anoptically active input fiber. The optically active input fiber includesa rare-earth dopant ion. The optical beam splitter also includes anoptical element having an input and at least one first output and onesecond output. The input is connected to the optically active inputfiber. The optical element is characterized by a first beam with a firstbeam power in a first direction and a second beam with a second beampower in a second direction. The second direction is different from thefirst direction. The optical beam splitter further includes a firstoutput fiber connected to the first output of the optical element and asecond output fiber connected to the second output of the opticalelement.

According to particular embodiments of the present invention, an opticalsystem is provided. The optical system includes an optical componenthaving an input and an output. The optical component may be an opticaltap, an optical modulator, an optical switching element, awavelength-division multiplexing (WDM) element, a fiber grating, a beamshaping element, a Diffractive Optical Element (DOE), or the like. Theoptical system also includes an optically active fiber connected to theinput of the optical component. The optically active fiber includes arare-earth dopant ion, for example, erbium or ytterbium. In someembodiments, a second optically active fiber is connected to the outputof the optical component.

In yet another embodiment, an optical system is provided that includesan optical component, for example, those listed above, having an inputand an output. The optical system also includes an optically activefiber connected to the output of the optical component. The opticallyactive fiber includes a rare-earth dopant ion, for example, erbium orytterbium.

Numerous benefits are achieved using the present invention overconventional techniques. For example, in an embodiment according to thepresent invention, SBS is reduced in optical components coupled to fiberamplifier systems. The reduction in SBS enables laser systems withincreased peak power in comparison to conventional systems. Variousadditional objects, features and advantages of the present invention canbe more fully appreciated with reference to the detailed description andaccompanying drawings that follow.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified schematic illustration of a high power fiberamplifier system according to an embodiment of the present invention;

FIG. 2 is a simplified schematic diagram illustrating an opticalisolator according to an embodiment of the present invention;

FIG. 3 is a simplified schematic diagram of an optical circulator systemwith reduced SBS according to an embodiment of the present invention;

FIG. 4 is a simplified schematic diagram illustrating a pump combinerwith reduced SBS according to an embodiment of the present invention;

FIG. 5 is a simplified schematic diagram illustrating a high power fiberamplifier according to an embodiment of the present invention;

FIG. 6 is a simplified schematic diagram illustrating a high power fiberamplifier according to another embodiment of the present invention; and

FIG. 7 is a simplified schematic diagram illustrating an optical beamsplitter with reduced SBS according to an embodiment of the presentinvention.

DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS

FIG. 1 is a simplified schematic illustration of a high power fiberamplifier system 100 according to an embodiment of the presentinvention. The fiber amplifier includes a rare-earth-doped fiber gainmedium 110. The rare-earth doping is typically ytterbium foramplification of light in wavelength range around 980 nm to 1100 nm.Other rare-earth elements, like erbium, neodymium, thulium, or the likecan be used for amplification at other wavelengths. In some embodiments,the doped fiber gain medium 110 is referred to as an optically activefiber. The optically active fiber includes a core extending along acentral axis of the fiber and a lower index cladding coaxiallysurrounding the core. In some embodiments, the optically active fiber isa double clad fiber including an additional cladding layer surroundingthe cladding layer adjacent the core. The core is typically made ofquartz glass doped with the rare-earth ion and the cladding layers aremade of quartz glass. One or more protective layers may be providedsurrounding the cladding layers.

The fiber gain medium is optically pumped by at least one pump source120 (e.g. a semiconductor laser), which is optically coupled to thefiber gain medium by a combiner 130, as is well known in the art.Optical coupling between the pump source 120 and the combiner 130, alsoreferred to as a pump combiner, is provided by one of severaltechniques. A low energy input optical pulse train 140 is substantiallyamplified by the optical amplifier 100 to become a high energy outputoptical pulse train 150.

According to FIG. 1, when operated in a pulsed mode, pulses of the inputtrain 140 are amplified to produce the output train 150. As illustrated,the intensity of the output pulses is greater than the intensity of theinput pulses. In some fiber amplifier systems as illustrated in FIG. 1or fiber laser systems, the output of the amplifier/laser at the splicelocation 180 is suitable for industrial applications including cutting,welding, marking, and the like. In order to reduce potential damage tothe end of the fiber at splice location 180, typical fiber systemsutilize a length of undoped relay fiber and an end cap that is splicedto the relay fiber. Relay fiber is a length of undoped fiber for whichthe waveguiding properties are designed to match or otherwise beessentially identical to the waveguiding properties of a correspondingdoped fiber to which the relay fiber is spliced. Because the waveguidingproperties are matched, an effective low-loss splice 180 can be used tocouple the active doped fiber to the relay fiber.

An end cap 164, which is a transparent member fusion bonded or welded tothe relay fiber, provides a material in which the beam can expand priorto reaching an interface with air. Thus, an end cap can be referred toas a beam expansion device or section. As the beam expands as it passesthrough the end cap, the beam intensity (W/cm.sup.2) decreases as thebeam waist expands, reducing the potential for damage at the interfacewith air. The end cap is typically made from synthetic quartz or otherglass material and may have non-parallel faces to reduce any reflectionsback into the laser system. In some applications, the end cap ischaracterized by a uniform index of refraction, providing an unguidedmedium. In other applications, the end cap is characterized by a lateralindex of refraction profile that provides some guiding of the beam as itpasses through the end cap. Generally, the undoped relay fiber and theend cap are purchased as a package that is spliced to the active fiberat splice location 180.

As a result of the intensity of the optical output provided by the laseramplifier 100, nonlinear effects such as SBS may occur in a passiverelay fiber that is spliced to the active fiber. The SBS present in thepassive relay fiber tends to reduce the system power, which isundesirable for many applications. The inventors have observed that SBSis most likely to occur at high levels with longer lengths of theundoped relay fiber. Since the undoped relay fiber serves merely totransfer light from the fiber amplifier to an optical component, itfollows that the buildup of SBS can be discouraged by making the undopedrelay fiber as short as possible or removing it altogether.

The inventors have also determined that SBS is more likely to beobserved in the undoped relay fiber than in the doped active fiber.Without limiting embodiments of the present invention, the inventorsbelieve that the reduced SBS empirically observed in the doped fibersmay be due to thermal gradients present in the doped fiber resultingfrom interaction between the optical mode in the doped fiber and theactive ions in the doped or optically active fiber. One theory ofoperation, which is not intended to limit the scope of embodiments ofthe present invention, is that the thermal gradient present in the dopedfiber results in a broadening of the effective SBS linewidth, therebyreducing SBS effects in the doped fiber. Alternatively, the inventorsbelieve that the reduced SBS observed in the doped fiber may result fromthe presence of dopant ions, which may serve to reduce the phononlifetime in the optically active fiber. Regardless of the actualphysical mechanism underlying the phenomena observed by the inventors,embodiments of the present invention utilize doped fiber in place ofconventional undoped fibers to reduce the presence of nonlinear effectsincluding SBS, increase output power from fiber laser systems, andbroaden the operating range of optical components utilized inconjunction with laser systems. Although some examples described hereinare applied in the context of SBS, one or more other non-linear effects,including self-phase modulation (SPS), stimulated Raman scattering(SRS), and the like, are reduced by embodiments of the presentinvention, enabling the production of high power outputs not availableusing conventional techniques. One of ordinary skill in the art wouldrecognize many variations, modifications, and alternatives.

Embodiments of the present invention provide a doped or optically activerelay fiber that can be used to couple a fiber amplifier or otheroptical device to an optical component. Because the SBS effect isgreater in undoped fiber than in doped fiber, the use of doped fiber forthe relay fiber results in a reduction in SBS or other non-lineareffects in one or more relay fibers attached to the optical component.Referring to FIG. 1, the output of the doped fiber 110 is coupled tooptical component 160 spliced to the output portion of the active fiber110 at splice location 180. The optical component 160 includes a doped(i.e., optically active) input relay fiber 162 coupled to an opticalelement 164. As described more fully throughout the presentspecification, the optical element may be one of a number of opticaldevices, such as an optical isolator, optical circulator, opticalmodulator, end cap, or the like. In the system illustrated in FIG. 1,the optical element 164 is an end cap that reduces the optical intensityat the glass/air interface on the right side of the end cap.

Embodiments of the present invention are not limited to the use of adoped relay fiber/end cap component coupled to the active fiber. Inconventional fiber amplifier and fiber laser designs using one or moredouble clad doped fibers as the active element, one or more ancillaryoptical components, such as mode-field adapters, fiber end-caps, pumpcombiners, and the like, utilize lengths of undoped relay fibers.Embodiments of the present invention utilize doped or optically activerelay fiber characterized by reduced SBS and other non-linear effects incomparison with conventional designs. Thus, although an end cap isillustrated in FIG. 1, embodiments of the present invention are notlimited to this particular optical element. One of ordinary skill in theart would recognize many variations, modifications, and alternatives.

FIG. 2 is a simplified schematic diagram illustrating a reduced SBSoptical isolator system according to an embodiment of the presentinvention. An optical isolator is an optical component that allows thetransmission of light in substantially only one direction. Applicationsfor optical isolators include their use to prevent unwanted reflectionsor feedback into a laser cavity or other optical system. Thus, opticalisolators in an embodiment have an input and an output and arecharacterized by an optic axis. Generally, the optic axis passes fromthe input to the output. The optical isolator is characterized by afirst transmittance in a first direction along the optic axis and asecond transmittance less than the first transmittance in a seconddirection opposite to the first direction. One of ordinary skill in theart would recognize many variations, modifications, and alternatives.

The optical isolator system 200 includes a first relay fiber 210, whichmay also be referred to as a first fiber pigtail optically coupled to anoptical isolator 220, which is optically coupled to a second relay fiber230. The optical isolator 220 may be one of several types, including aFaraday rotation-based, a calcite polarizer-based, a Brewster's angleplate polarizer-based isolator, or the like. The first fiber pigtail 210is an optically active or doped fiber according to embodiments of thepresent invention. In a particular application, the input of the firstrelay fiber is spliced to an output of a fiber laser or fiber amplifier.In addition to providing waveguiding suitable for a low-loss splice, thedoped relay fiber 210 serves to reduce SBS present in the relay fiber.Thus, the reduction in the amount of SBS present in the relay fiberresults in less backward coupling of radiation into the laser oramplifier. Thus, by utilizing the optical isolator system illustrated inFIG. 2, the power available at the output of the optical isolator systemis increased.

The doped relay fiber 210 may be a single mode or a multimode fiber.Additionally, the doped relay fiber may be a single clad, double clad,or other multiple clad optical fiber. In a particular embodiment, thecore of a double clad fiber is doped with a rare-earth ion such aserbium, ytterbium, neodymium, thulium, or the like. The dopant levels inthe relay fiber may be equal to the dopant levels in the active fiberused in a laser or amplifier system. Alternatively, the dopant levels inthe relay fiber may be less than or greater than dopant levels insystems coupled to the doped relay fiber. The dopant levels in the relayfiber may be substantially constant as a function of fiber length orvary as appropriate to the particular application.

In another embodiment, both the first relay fiber 210 and the secondrelay fiber 230 are doped fibers characterized by reduced SBS effects.In an alternative embodiment, only the second relay fiber 230 is a dopedfiber.

Although a doped relay fiber has been applied in the context of anoptical isolator in the embodiment illustrated in FIG. 2, embodiments ofthe present invention are not limited to this particular opticalcomponent. Other optical components in which the laser intensity is suchthat non-linear effects, including SBS, are not insignificant are alsoincluded within the scope of the present invention. Thus, embodiments ofthe present invention utilize doped relay fiber in conjunction withvarious different optical components. As examples, a number of variousoptical components including doped relay fibers are described moreparticularly throughout the present specification.

As illustrated by the doped relay fiber and end cap in FIG. 1,embodiments of the present invention provide doped relay fiber incombination with one or more optical elements. FIG. 3 is a simplifiedschematic diagram of an optical circulator system with reduced SBSeffects according to an embodiment of the present invention. The opticalcirculator system 300 illustrated in FIG. 3 includes a three portoptical circulator 310. The three port optical circulator 310 has aninput end 312, a dual-purpose input/output end 314, and an output end316. In embodiments that use a four port optical circulator, anadditional dual-purpose input/output end (not illustrated) is providedin addition to the dual purpose input/output end 314. One of ordinaryskill in the art would recognize many variations, modifications, andalternatives.

Generally, conventional optical circulators are passive devices thatapply the Faraday effect or another non-reciprocal optical process tocause light to pass from port 1 (312) to port 2 (314) to port 3 (316) ina single direction. Light entering at port 2 will pass to port 3.Typical optical circulators are packaged with a length (e.g., 1 meter)of undoped relay fiber connected to each of the ports or ends. In theembodiment of the present invention illustrated in FIG. 3, a length ofdoped relay fiber 322 is utilized to provide the input to the input end312, a second length of doped relay fiber 324 is utilized toprovide/receive the input/output to/from the dual-purpose input/outputend 314, and a third length of doped relay fiber is utilized to transmitthe output from the output end 316. In other embodiments, only one ofthe relay fibers 322/324/326 are doped as appropriate to the particularapplication. In yet other embodiments, two of the three relay fibers aredoped as appropriate to other particular applications. In embodimentsutilizing a four port optical circulator, one, two, three, or all fourrelay fibers are doped to reduce SBS effects.

In applications in which a high power input is provided to the input end312 of the optical circulator, the use of a doped relay fiber 322 willreduce the SBS effect in the optical circulator package 300 and therebyimprove system performance. In applications in which a high power inputis provided at the dual-purpose input/output end 314, the use of a dopedrelay fiber 324 will reduce the SBS effect in the optical circulatorpackage 300 and thereby improve system performance. One of ordinaryskill in the art would recognize many variations, modifications, andalternatives. As an example of a system with a high power input at thedual-purpose input/output end 314, reference is made to FIG. 5 in whichlight from the double-pass amplifier 550 is input into the opticalcirculator 520 after passing through the amplitude modulator 530.

According to another embodiment of the present invention, a pumpcombiner includes a section of doped or active fiber. FIG. 4 is asimplified schematic diagram illustrating a pump combiner 400 withreduced SBS according to an embodiment of the present invention. A pumpcombiner, sometimes referred to as a pump coupler or a fiber combiner,is an optical element that receives pump light from a pump source andsignal light from a signal source and injects the two received signalsinto a fiber optic cable. Various architectures of pump combiners areincluded within the scope of embodiments of the present invention. In aparticular architecture, a length of fiber configured to receive thepump light (pump fiber) and a length of fiber configured to receive thesignal light (signal fiber) are brought into physical contact and heatedto fuse the fibers. As pump light in the pump fiber passes through thefused fiber portion, optical coupling between the fibers transfers thepump light from the pump fiber to the signal fiber.

In conventional pump combiner designs, the pump fiber and the signalfiber are undoped relay fibers. Thus, both the pump light and signallight are injected into undoped relay fiber. The undoped signal fiber isthen connected to one end of a length of doped or active fiber, e.g., aninput of a fiber amplifier. In the embodiment of the present inventionillustrated in FIG. 4, pump light from pump source 410 is injected intopump fiber 412. Signal light is injected from a signal source (notshown) into signal fiber 420. In the illustrated embodiment, the pumpfiber and the signal fiber are joined in fused or coupling section 430.The pump fiber is terminated by an angled cleaved facet 414 to reducestray reflections back into the pump fiber. The signal fiber 420 is anactive fiber in an embodiment of the present invention, thereby reducingSBS present in the signal fiber. In another embodiment, the pumpcombiner injects both the signal light and the pump light into a lengthof doped fiber.

According to an embodiment of the present invention, a pump combinerincludes a pump fiber having a first end configured to receive a pumpsource and a second end. The second end may be terminated by an angledfacet. The pump combiner also includes a signal fiber optically coupledto the pump fiber in a coupling section. The coupling section mayinclude a fused section in which light propagating in the pump fiberenters into and propagates in the signal fiber. Thus, the claddingsections of the pump fiber and the signal fiber may be fused to enableone or more modes propagating in the pump fiber to couple into thecladding of the signal fiber (e.g., into an inner cladding of adouble-clad signal fiber). Various designs of pump combiners or pumpcouplers are included within the scope of embodiments of the presentinvention. The signal fiber includes a first end configured to receivesignal light and a second end configured to support both the pump lightand the signal light. The coupling section is disposed between the firstend and the second end. The signal fiber is an optically active fiber,for example, including a rare-earth doped core.

The active signal fiber will provide for reductions in SBS occurring inthe signal fiber, thereby improving system performance. The output endof the active signal fiber is typically spliced to the input of theactive fiber of a fiber amplifier section. Thus, embodiments of thepresent invention provide pump combiners that are drop-in replacementsfor conventional pump combiners, while providing benefits (e.g., reducedSBS) not available using conventional pump combiners.

FIG. 5 is a simplified schematic diagram illustrating a high power fiberamplifier according to an embodiment of the present invention. Highpower pulsed amplifier 500 includes a seed source 510 that generates aseed signal (either pulsed or CW) that is injected into a first port 514of an optical circulator 520. According to an embodiment of the presentinvention, the optical seed signal is generated by using a seed source510 that is a continuous wave (CW) semiconductor laser. In a particularembodiment, the CW semiconductor laser is a fiber Bragg grating (FBG)stabilized semiconductor diode laser operating at a wavelength of 1032nm with an output power of 20 mW. In another particular embodiment, theCW semiconductor laser is an external cavity semiconductor diode laseroperating at a wavelength of 1064 nm with an output power of 100 mW. Theoutput power may be lower or greater than 100 mW. For example, theoutput power can be 50 mW, 150 mW, 200 mW, 250 mW, or the like. Inalternative embodiments, the seed signal is generated by a compactsolid-state laser or a fiber laser. One of ordinary skill in the artwould recognize many variations, modifications, and alternatives.

After passing through the optical circulator 520, the seed signal exitsfrom a second port 522 of the circulator 520 and impinges on a firstside 532 of an optical amplitude modulator 530. Circulators are wellknown in the art and are available from several suppliers, for example,model OC-3-1064-PM from OFR, Inc. of Caldwell, N.J.

The optical amplitude modulator 530 is normally held in an “off” state,in which the signal impinging on the modulator is not transmitted.According to embodiments of the present invention, optical amplitudemodulator provides amplitude modulation and time-domain filtering of theseed signal as well as amplified spontaneous emission (ASE) filtering.In a particular embodiment, the length of the optical pulse isdetermined by the operation of the optical amplitude modulator 530,which may be an APE-type Lithium Niobate Mach-Zehnder modulator having abandwidth >3 GHz at 1064 nm.

According to embodiments of the present invention, the optical amplitudemodulator 530 is an electro-optic Mach-Zehnder type modulator, whichprovides the bandwidth necessary for generating short optical pulses. Inother embodiments, the optical amplitude modulator 530 is a phase orfrequency modulator with a suitable phase or frequency to amplitudeconverter, such as an edge optical filter, an extinction modulator, oran acousto-optic modulator. For example, an electro-optic phasemodulator can induce a frequency chirp to the optical signal, whichwould be converted into an amplitude modulation when the optical signalis transmitted through a short or long pass optical filter. Preferably,the optical signal would be characterized by a wavelength thatexperiences high loss when no electrical signal is applied to theelectro-optic phase modulator. When an electrical signal is applied tothe electro-optic phase modulator, the optical signal preferablyexperiences a change in wavelength or frequency chirp to a valuecharacterized by low optical loss.

In order to pass the seed signal, the optical amplitude modulator 530 ispulsed to the “ton” state for a first time to generate an optical pulsealong optical path 536. The pulse width and pulse shape of the opticalpulse generated by the optical amplitude modulator 530 are controlled bythe modulator drive signal applied to the optical amplitude modulator530. The optical pulse then passes for a first time through a firstoptical amplifier 550, where it is amplified. According to embodimentsof the present invention, the amplitude modulator, driven by a timevarying drive signal, provides time-domain filtering of the seed signal,thereby generating a laser pulse with predetermined pulsecharacteristics, including pulse width, pulse shape, and pulserepetition rate.

According to an embodiment of the present invention, the opticalamplifier 550 is an optical fiber amplifier. Fiber amplifiers utilizedin embodiments of the present invention include, but are not limited torare-earth-doped single-clad, double-clad, or even multiple-clad opticalfibers. The rare-earth dopants used in such fiber amplifiers includeytterbium, erbium, holmium, praseodymium, thulium, or neodymium. In aparticular embodiment, one or more of the fiber-optic based componentsutilized in constructing optical amplifier 550 utilizepolarization-maintaining single-mode fiber.

Referring to FIG. 5, in embodiments utilizing fiber amplifiers, a pump542 is coupled to a rare-earth-doped fiber loop 544 through opticalcoupler 540. In the embodiment illustrated in FIG. 5, the opticalcoupler 540 includes doped relay fibers as described in relation to FIG.4. Thus, SBS is reduced in the doped coupler according to embodiments ofthe present invention. Generally, a semiconductor pump laser is used aspump 542. One of ordinary skill in the art would recognize manyvariations, modifications, and alternatives. In alternative embodiments,the optical amplifier 550 is a solid-state amplifier including, but notlimited to, a solid-state rod amplifier, a solid-state disk amplifier,or gaseous gain media.

In a particular embodiment, the optical amplifier 550 includes a 5 meterlength of rare-earth doped fiber 544, having a core diameter ofapproximately 4.1.mu.m, and doped with ytterbium to a doping density ofapproximately 4.times.10.sup.24 ions/m.sup.3. The amplifier 550 alsoincludes a pump 542, which is an FBG-stabilized semiconductor laserdiode operating at a wavelength of 976 nm, and having an output power of100 mW. The output power can be lower or greater than 100 mW. Forexample, it can be 50 mW, 150 mW, 200 mW, 250 mW, 300 mW, 350 mW, 400mW, or the like. In another particular embodiment, the pump 142 is asemiconductor laser diode operating at a wavelength of about 915 nm. Inyet another particular embodiment, the pump 542 is a semiconductor laserdiode operating at an output power of 450 mW or more. In a specificembodiment, the amplifier 550 also includes a pump to fiber coupler 540,which is a WDM pump combiner including doped relay fiber.

The signal emerging from optical amplifier 550 along optical path 548then impinges on a reflecting structure 546, and is reflected back intooptical amplifier 550. The signal passes for a second time throughoptical amplifier 550, wherein the signal is amplified. The reflectingstructure 546 performs spectral domain filtering of the laser pulse andof the amplified spontaneous emission (ASE) propagating past opticalpath 548. Thus, the seed signal experiences both amplitude andtime-domain modulation passing through amplitude modulator 530, andspectral-domain filtering upon reflection from reflecting structure 546.

In an embodiment, the reflecting structure 546 is a fiber Bragg grating(FBG) that is written directly in the fiber used as the opticalamplifier 550. The periodicity and grating characteristics of the FBGare selected to provide desired reflectance coefficients as is wellknown in the art. Merely by way of example in a particular embodiment,the reflecting structure 546 is a FBG having a peak reflectance greaterthan 90%, and a center wavelength and spectral width closely matched tothe output of the seed source 510.

The signal emerging from optical amplifier 550 along optical path 536impinges on the second side 534 of the optical amplitude modulator 530,which is then pulsed to the “on” state a second time to allow theincident pulse to pass through. According to embodiments of the presentinvention, the timing of the second “on” pulse of the optical amplitudemodulator 530 is synchronized with the first opening of the modulator530 (first “on” pulse) to take account of the transit time of the signalthrough the amplifier 550 and the reflecting structure 546. Afteremerging from the first side of the optical amplitude modulator 530, theamplified pulse then enters the second port 522 of optical circulator520, and exits from the third port 516 of optical circulator 520 alongoptical path 548. In some embodiments, the intensity passing through theoptical circulator 520 is sufficient to result in SBS in the fibersutilized in conjunction with the optical circulator. Thus, someembodiments, utilize an optical circulator including doped relay fibersare described in relation to FIG. 3.

The signal is then amplified as it passes through a second opticalamplifier 560. Embodiments of the present invention utilize a fiberamplifier as optical amplifier 560, including a pump 554 that is coupledto a rare-earth-doped fiber loop 556 through an optical coupler 552. Asdiscussed in relation to the optical coupler 540, some embodimentsutilize doped relay fiber to decrease the incidence of SBS in theoptical coupler 552.

Generally, a semiconductor pump laser is used as pump 554, althoughpumping of optical amplifiers can be achieved by other means as will beevident to one of skill in the art. In a particular embodiment, thesecond optical amplifier 560 includes a 5 meter length of rare-earthdoped fiber 556, having a core diameter of approximately 4.8.mu.m, andis doped with ytterbium to a doping density of approximately6.times.10.sup.24 ions/m.sup.3. The amplifier 560 also includes a pump554, which is an FBG-stabilized semiconductor laser diode operating at awavelength of 976 nm, and having an output power of 500 mW. In anotherparticular embodiment, the second optical amplifier 560 includes a 2meter length of rare-earth doped fiber 556, having a core diameter ofapproximately 10.mu.m, and is doped with ytterbium to a doping densityof approximately 1.times.10.sup.26 ions/m.sup.3. The fiber length can beshorter or longer than 2 meters. For example, it can be 1.0 m, 3.0 m,3.5 m, 4.0 m, 4.5 m, 5.0 m, or the like. The amplifier 560 can alsoinclude a multimode pump 554, which is a semiconductor laser diodehaving an output power of 5 W. The output power can be lower or greaterthan 5 W. For example, it can be 3 W, 4 W, 6 W, 7 W, 8 W, 9 W, 10 W, orthe like.

In an embodiment, the fiber 570 at the output of the rare-earth dopedfiber 556 is a doped fiber optically coupled to an end cap as discussedin relation to FIG. 1. Thus, at the output of the second amplifier 560,where the pulsed light intensity is high, doped relay fibers areutilized in conjunction with an end cap (not shown) to reduce theincidence of SBS in the amplifier system.

Although FIG. 5 illustrates the use of a single optical amplifier 560coupled to the third port of the optical circulator 520, this is notrequired by the present invention. In alternative embodiments, multipleoptical amplifiers are utilized downstream of the optical circulator 520as appropriate to the particular applications. Doped relay fiber inoptical couplers could also be utilized as appropriate in multipleoptical amplifier designs. One of ordinary skill in the art wouldrecognize many variations, modifications, and alternatives.

Although embodiments of the present invention have been discussed inrelation to the fiber amplifier system illustrated in FIG. 5,embodiments of the present invention are not limited to the particulararchitecture illustrated in FIG. 5. Other laser and/or amplifierarchitectures are suitable for application of some embodiments,including architectures described in U.S. patent application Ser. No.11/737,052, entitled “Method and System for Tunable Pulsed LaserSource,” filed on Apr. 18, 2007, U.S. patent application Ser. No.11/942,984, entitled “Fiber Amplifier with Integrated Fiber Laser Pump,”filed on Nov. 20, 2007, and U.S. patent application Ser. No. 12/015,427,entitled “Seed Source for High Power Optical Fiber Amplifier,” filed onJan. 16, 2008, the disclosures of which are hereby incorporated byreference for all purposes.

FIG. 6 is a simplified schematic diagram illustrating a high power fiberamplifier according to another embodiment of the present invention. Forpurposes of clarity, common elements between FIG. 5 and FIG. 6 arereferenced with common reference numbers. The output 570 of the opticalamplifier 560 is coupled to optical isolator 610. In the embodimentillustrated in FIG. 6, the optical isolator 610 includes one or morelengths of doped relay fiber, thus suppressing SBS and other non-lineareffects. Exemplary optical isolators including doped relay fiber areillustrated in FIG. 2. A second single-pass optical amplifier 620 isillustrated as another fiber amplifier. The optical amplifier 620includes fiber loop 626 and an optical coupler 622 receiving a pumpsignal from pump source 624. As discussed in relation to FIG. 5, theoptical coupler 622 may include one or more lengths of doped relayfiber. Output fiber 628 is a doped relay fiber coupled to end cap 630 asdiscussed in relation to FIG. 1. Thus, many of the components exposed tohigh intensity light are configured to reduce SBS and other non-lineareffects via the use of doped relay fiber.

It should be noted that although the pump coupler 622 has beenillustrated as between the optical isolator 610 and the active fiber626, this is not required by embodiments of the present invention. Pumpcouplers could be joined to the fiber amplifier sections, for example,between the end cap 630 and the length of active fiber 626. Thus, bothforward pumping configurations, as illustrated in FIG. 6, and backwardpumping configurations in which pump light travels in a directionopposing the signal light, are included within the scope of embodimentsof the present invention. Similar placement of optical couplers 540 and552 are applicable to optical amplifiers 550 and 560.

An exemplary optical beam splitter including doped relay fiber isillustrated in FIG. 7. An input fiber 710 is coupled to an optical beamsplitter 720. The input fiber 710 is an optically active fiber includinga rare-earth doped fiber to reduce SBS present in the input fiber 710.The beam splitter 720 may split the beam into at least two or morebeams. Each beam may have a different beam direction or different beampower. A first output fiber 730 and a second output fiber 740 arecoupled to the beam splitter 720. In some embodiments, there may be aplurality of beams output from the beam splitter 720 and each beam mayhave substantially equal power. The output fibers may also be opticallyactive fiber including a rare-earth doped fiber to reduce SBS present inthe output fibers 730 and 740.

Embodiments of the present invention are not limited to the opticalcomponents discussed above. Other embodiments provide optical systemsthat include an optically active fiber (either an input or output fiber)connected to an optical component. The optically active fiber includes arare-earth dopant ion. The optical component may include one or more ofthe following: an optical modulator, an optical switching element, awavelength-division multiplexing (WDM) component, a fiber grating, abeam shaping element, an optical tap, a Diffractive Optical Element(DOE), or the like. One of ordinary skill in the art would recognizemany variations, modifications, and alternatives.

In a particular embodiment, wavelength-division multiplexing (WDM)technology multiplexes multiple optical signals on a single opticalfiber by using laser of different wavelengths to carry differentsignals, for example, in fiber optic communications applications.According to embodiments of the present invention, the single fiber maybe an optically active fiber including a rare-earth dopant ion.

In another embodiment, an optical switch enables signals in opticalfibers or integrated optical circuits to be selectively switched fromone fiber to another. According to embodiments of the present invention,the optical fibers may include an optically active fiber including arare-earth dopant ion.

In a further embodiment, a fiber Bragg grating (FBG), which is a type ofreflector constructed in a short segment of optical fiber that reflectsparticular wavelengths of light and transmits all other wavelengths oflight, may be optically connected to an active relay fiber. The fiberBragg grating is constructed by adding a periodic variation to therefractive index of the fiber core, which generates a dielectric mirrorover a particular wavelength range. The fiber Bragg grating may also beused as an inline optical filter to block certain wavelengths. Oneapplication of the fiber Bragg grating is in optical communicationssystems. The fiber Bragg grating is specifically used as filters or inoptical multiplexers with an optical circulator. The FBG may beconnected to at least one input fiber and one output fiber, where theinput fiber or output fiber may be optically active fibers including arare-earth dopant ion.

A Diffractive Optical Element (DOE) is a set of lengthwise and crosswisealigned identical unit patterns. The DOE with unit patterns diffracts abeam into a plurality of divided beams on an image plane. The DOE may besuitable for high speed and low cost laser processing. According toembodiments of the present invention, the input fiber connected to theDOE may be an optically active fiber including a rare-earth dopant ion.

According to embodiments of the present invention, a method ofconstructing an optical system includes connecting an optically activeinput fiber to an optical component, where the optically active inputfiber includes a rare-earth dopant ion. The optical component may be oneof the following: an optical coupler, an optical amplifier, an opticalcirculator, an optical isolator, an optical modulator, an opticalswitching element, a wavelength-division multiplexing (WDM), a fibergrating, a beam shaping element, an optical tap, a Diffractive OpticalElement (DOE), or the like. The method further includes connecting anoutput fiber to the optical component, where the output fiber may be anoptically active fiber including a rare-earth dopant ion. As describedthroughout the present specification, a benefit of using an opticallyactive fiber is the reduction of SBS present in fibers coupled orconnected to one or more of the above optical components.

Although some embodiments described above utilize a doped fiberconnected to the input of the optical component, the invention is notlimited to doped fiber pigtails on the input side of the opticalcomponent. In other embodiments, the doped fiber is connected to theoutput of the optical component or to both the input and the output ofthe optical component. Although a listing of optical components has beendescribed herein, the list of optical components included within thescope of the present invention is not limited to the particularcomponents described herein but also includes other optical componentsthat are suitable for fiber coupling. One of ordinary skill in the artwould recognize many variations, modifications, and alternatives.

While the present invention has been described with respect toparticular embodiments and specific examples thereof, it should beunderstood that other embodiments may fall within the spirit and scopeof the invention. It will be apparent to those skilled in the art thatother alternatives, variations, and modifications are possible, andshould be seen as being within the spirit and the scope of theinvention. The scope of the invention should, therefore, be determinedwith reference to the appended claims along with their full scope ofequivalents.

What is claimed is:
 1. An optical isolator system comprising: anoptically active input fiber; an optical element having an input and anoutput, the input coupled to the optically active input fiber, whereinthe optical element is characterized by an optic axis, a firsttransmittance in a first direction along the optic axis, and a secondtransmittance less than the first transmittance in a second directionopposite to the first direction; and an output fiber coupled to theoutput of the optical element.
 2. The optical isolator system of claim 1wherein the output fiber comprises an optically active fiber.
 3. Theoptical isolator system of claim 1 wherein the optically active inputfiber comprises a double-clad fiber including a rare-earth doped core.4. The optical isolator system of claim 1 wherein the optical elementcomprises a Faraday isolator.
 5. A laser source comprising: a seedsource; an optical circulator including a first port coupled to the seedsource, a second port, and a third port; an amplitude modulatorcharacterized by a first side and a second side, wherein the first sideis coupled to the second port of the optical circulator; and a firstfiber amplifier characterized by an input end and a reflective end,wherein the input end is coupled to the second side of the amplitudemodulator, the first fiber amplifier comprising: an active fibersection; a pump source coupled to the active fiber section by a pumpcoupler, wherein the pump coupler includes a rare-earth doped fiber; anda second fiber amplifier coupled to the third port of the opticalcirculator.
 6. The laser source of claim 5 wherein the active fibersection comprises a double clad fiber including a rare-earth dopant ion.7. The laser source of claim 5 wherein the second fiber amplifiercomprises: a second active fiber section; and a second pump sourcecoupled to the second active fiber section by a second pump coupler,wherein the second pump coupler includes a second rare-earth dopedfiber.
 8. The laser source of claim 5 wherein the second fiber amplifiercomprises a polarization-maintaining fiber.
 9. The laser source of claim5 further comprising: a doped fiber coupled to the second fiberamplifier; and a beam expansion section joined to the doped fiber. 10.The laser source of claim 5 wherein the reflective end of the firstfiber amplifier comprises a Fiber Bragg Grating (FBG).
 11. An opticalcoupler comprising: a first fiber including an input facet configured toreceive a pump source; a second fiber including an input facetconfigured to receive a signal source, wherein the second fiber includesa rare-earth dopant ion; and a coupling section between the first fiberand the second fiber.
 12. The optical coupler of claim 11 wherein thesecond fiber comprises a core including the rare-earth dopant ion, afirst cladding surrounding the core, and at least a second claddingsurrounding the first cladding.
 13. The optical coupler of claim 11wherein the rare-earth dopant ion comprises at least one of erbium orytterbium.
 14. The optical coupler of claim 11 wherein a cladding of thefirst fiber is fused to a cladding of the second fiber in the couplingsection.
 15. An optical beam splitter comprising: an optically activeinput fiber, the optically active input fiber including a rare-earthdopant ion; an optical element having an input and at least one firstoutput and one second output, the input connected to the opticallyactive input fiber, wherein the optical element is characterized by afirst beam with a first beam power in a first direction and a secondbeam with a second beam power in a second direction, wherein the seconddirection is different from the first direction; a first output fiberconnected to the first output of the optical element; and a secondoutput fiber connected to the second output of the optical element. 16.The optical beam splitter of claim 15 wherein the second beam power issubstantially equal to the first beam power.
 17. The optical beamsplitter of claim 15 wherein the rare-earth dopant ion comprises atleast one of erbium or ytterbium.
 18. The optical beam splitter of claim15 wherein the optical element comprising a plurality of outputs, eachoutput having a beam with a respective beam power and beam direction.19. An optical system comprising: an optical tap having an input and anoutput; and an optically active fiber connected to the input of theoptical tap, wherein the optically active fiber includes a rare-earthdopant ion.
 20. The optical system of claim 19 wherein the rare-earthdopant ion comprises at least one of erbium or ytterbium.
 21. Theoptical system of claim 19 further comprising a second optically activefiber connected to the output of the optical tap.
 22. An optical systemcomprising: an optical component including at least one of an opticalmodulator or an optical switching element, the optical component havingan input and an output; and an optically active fiber connected to theinput of the optical component, wherein the optically active fiberincludes a rare-earth dopant ion.
 23. The optical system of claim 22wherein the rare-earth dopant ion comprises at least one of erbium orytterbium.
 24. The optical system of claim 22 further comprising asecond optically active fiber connected to the output of the opticalcomponent, the second optically active fiber including a rare-earthdopant ion.
 25. An optical system comprising: an optical componentincluding at least one of wavelength-division multiplexing (WDM) elementor a fiber grating, the optical component having an input and an output;and an optically active fiber connected to the input of the opticalcomponent, wherein the optically active fiber includes a rare-earthdopant ion.
 26. The optical system of claim 25 wherein the rare-earthdopant ion comprises at least one of erbium or ytterbium.
 27. Theoptical system of claim 25 further comprising a second optically activefiber connected to the output of the optical component.
 28. An opticalsystem comprising: a beam shaping element having an input and an output;and an optically active fiber connected to the input of the beam shapingelement, wherein the optically active fiber includes a rare-earth dopantion.
 29. The optical system of claim 28 wherein the rare-earth dopantion comprises at least one of erbium or ytterbium.
 30. The opticalsystem of claim 28 further comprising a second optically active fiberconnected to the output of the beam shaping element.
 31. An opticalsystem comprising: a Diffractive Optical Element (DOE) having an inputand an output; and an optically active fiber connected to the input ofthe DOE, wherein the optically active fiber includes a rare-earth dopantion.
 32. The optical system of claim 31 wherein the rare-earth dopantion comprises at least one of erbium or ytterbium.
 33. The opticalsystem of claim 31 further comprising a second optically active fiberconnected to the output of the DOE.